Noninvasive imaging of rat-derived microglia and its reactivity to inflammatory molecules via acoustic impedance microscopy.

PURPOSE: Microglia, the brain's immune cells, play important roles in neuronal differentiation, survival, and death. The function of microglia is deeply related to the morphologies; however, it is too complex to observe conventionally and identify the condition of living microglia using optical microscopes. Herein, we proposed a new method to observe living cultured microglia and their reactivity to inflammation via the acoustic impedance mode of a scanning acoustic microscope. METHODS: Primary cultured microglia collected from rat pups exposed to acetamiprid, an insecticide, in utero were observed with both acoustic interface impedance mode (C-mode) and transparent three-dimensional impedance mode (B-mode). RESULTS: We characterized microglia into four types based on the results obtained from acoustic impedance, cytoskeletal information, and laser confocal imaging. Biphasic acoustic observation using B-mode and C-mode gave us information regarding the dynamic morphologies of living microglia treated with adenosine triphosphate (ATP) (600 µmol/L), which reflects distress signals from inflamed neurons. Acetamiprid exposure induced microglia response even in the neonatal period. ATP stimulus altered the shape and thickness of microglia with a change in the bulk modulus of the cell. Three-dimensional alteration with ATP stimulus could be observed only after biphasic acoustic observation using B-mode and C-mode. This acoustic observation was consistent with confocal observation using anti-Iba-1 and P2Y12 immunocytochemistry. CONCLUSION: This study demonstrated the adequacy of using a scanning acoustic microscope in analyzing microglia's shape, motility, and response to inflammation.

Time and frequency domain deconvolution for cross-sectional cultured cell observation using an acoustic impedance microscope.

Herein, we propose a method to estimate the reflection coefficient of the ultrasonic wave transmitted onto an object and to display this with acoustic impedance distribution. The observation targets were glial cells, which have a rigid cytoskeleton and spread out well on a culture substrate. A reflection coefficient derived only from the cells was then obtained using a deconvolution process. In the conventional method, the deconvolution process that was performed only in the frequency domain would cause an error in the reconstructed signal, and it formed an artifact when the result was converted into the acoustic impedance image. To solve this problem, two types of deconvolution techniques were applied in either the full frequency or time-frequency domain. The results of both methods were then compared. Since the characteristic acoustic impedance is a physical property substantially equivalent to the bulk modulus, it can be considered that the internal elastic parameter is thus estimated. An analysis of the nucleus based on its position in the acoustic impedance image was then performed. The results indicated that the proposed time-frequency domain deconvolution method is able to maintain the structure of the cell, while the cell itself is free from unwanted artifacts. The nucleus was also estimated to be located toward the center of the cell, with lower acoustic impedance value than the cytoskeleton. The results of this study could contribute to establishing a method for monitoring the internal condition of cultured cells in regenerative medicine and drug discovery.